Eper014384.1


Basic Information
Transcription Factor Domain
Sequence Information
Similer Transcription Factors

Basic Information

Insect
Eristalis pertinax
Gene Symbol
Myrf
Assembly
GCA_907269125.1
Location
OU026150.1:5693155-5701735[+]

Transcription Factor Domain

TF Family
NDT80_PhoG
Domain
NDT80_PhoG domain
PFAM
PF05224
TF Group
Unclassified Structure
Description
This family includes the DNA-binding region of NDT80 [2] as well as PhoG and its homologues. The family contains Swiss:Q05534 or VIB-1. VIB-1 is thought to be a regulator of conidiation in Neurospora crassa and shares a region of similarity to PHOG, a possible phosphate nonrepressible acid phosphatase in Aspergillus nidulans. It has been found that vib-1 is not the structural gene for nonrepressible acid phosphatase, but rather may regulate nonrepressible acid phosphatase activity [1].
Hmmscan Out
# of c-Evalue i-Evalue score bias hmm coord from hmm coord to ali coord from ali coord to env coord from env coord to acc
1 1 1.6e-37 2.6e-33 115.6 0.9 2 180 412 558 411 558 0.96

Sequence Information

Coding Sequence
ATGGAATACACAAGGTCCTTGAACGGTCGATCAGATTTTATTGGAGGAATAGATAACGAAGCACTAGACTTCGGACTAGATCAATTTATACACGTCTCCGCGTCGACGGGTGGAACGAATGCATCACCAGCCGTGTCCACGGTCGACGTAGGCACGTCAAGCACACACTCCGCACAGACCCAGACAAGCTTGCCAGAGAGCCCACCCGATTCTGGGTCAGAGCCGCCATACAGCCCAGGCGACTTGCAGGGCCTCACGCTTACGTCGCGGGCCACATCGTGCCGCTGCAACGCGGCCACCGATGGCACAATCATCGGTGCCCGCAGCCCACTATGCAGCCACCAGCAGATGAAGACCGCGTCAGATATTCACCCTCTGACGCACATCCCACACCAGATGCAACCCGGtatccaccaccagcaccaccacctgTACACTGACCACGCCGAGCAACACTCCCTGCTACTGGCAGCTACACCGCATATGCACCCGCAGGGCAGTGGCATCTATGGCAGCCCTGACAACCGGCACGACAGAAGCGTGGTGGTTCACGAGCACCCGGACACCCTGCTCGACATTGACGGCCACCATCCGAAATCCCACGTGCACAGCAACATTCATGTGGcgacaataaatgaaattatgGACATAGACGCGCAGCGGTCGTCGTACAGCAGACAGCCGATGATTATGAATccccagcaccagcaccagctgaCGTCGTCCATCATTCCGTCGGACGTCTACATGGGCACACCGGCTCCCATCATTGAGACGCCGGCTGTGCATGCGCCTACGCGCAAACGCAAGCTCTCCCAAGTTGAGTGCTGCACCTCAATGCTGACCATCAAGCCAGAACCTGGTGCATCCATGAGCCCAATGAGTCTGCAAAAGACTAACCCAACATCCCCCGTCACGATCAACTTGCAGGGCACTGACGGGGGATCTCCGTCCCTGTCATCACTCTCGCCCACCGCCACCAGCTTGTCCCTGTCGAACGACAACAATAGCCTGGATGGAGTCGGTGCCGGCACCCCAAACGGGGCCGGATTCGTGGGCTCGAACGGCACCGACTCATCCAGCGAGTCCTCACCAATGCAATGCATTCGTTTTAGTCCATTCCAGCAGCATAATTGGCACACTCTCTGCGACCAGAGCCTCCAGGAGCTGACCATCGCGCACTACCGCGTCGATGCCGATAAGggttttaatttttctgtttctgatGACGCCTTTGTGTGtcagaagaaaaatcattttcaaatcacCTGCCATGCCCGCCTGCACGGTGATGCGAAATTTGTACGAACCCCATCGGGCCTTGAAAAAATCAAGTCATTCCATCTGCATTTCTACGGCGTCAAGCTGGAGGCTCCCAATCAGACCATTCGCGTCGAGCAGAGCCAGTCGGATCGATCGAAGAAGCCCTTCTACCCCGTACCGATCGACTTGCAGAGCCACCTCGTGAGCAAGGTAACCGTTGGCCGATTGCATTTCTCTGAGACCACAAACAACAACATGCGCAAGAAGGGACGCCCCAATCCGGAGCAGCGCTACTTCCAACTGGTCGTCGGTCTGCACGTTCACACCCATTCTGGCCACTTCCCGGTGGTGAGCCAGGGCAGCGAACGCATCATTGTGCGCGCCTCGAATCCGGGCCAGTTCGAGAGTGacgttgaactctgctggcagAGGGGCATAACGCCCGAGTCGATATTCCACGCAGGTCGCGTCGGCATCAATACGGACCGTCCCGACGAGAGTCTCGTGATACATGGAAATCTGAAGGTGTCCGGCCATATTATTCAGCCGAGCGACAGTCGGGCAAAGCAAGAGATCAGCGAGCTGGACACAGCTGTTCAGCTGAAGAATCTTCAGAAAATACGAATTGTCCGGTACCGCTATGAGCCGGAATTCGCGCTACACTCGGGCCTGAAGTCGCGCATGGACAACGAGGAGATCGTCGATACGGGCGTCATTGCACAGGAGGTGCGCGAAGTCTTGCCGGACGCTGTCCAAGAAGCGGGGAGCATTGTCCTTCCGAGTGGACAGGTGATTGAGAATTTCCTGCTAGTGAACAAGGATCGTATTTTGATGGAAAACATTGGCGCTGTAAAGGAACTATGCAAGGTGACCGGCTCGCTGGAGACCCGGATCGAGCAGCTGGAAAAGATGAACAAACGCCTACTGAGAATGCAAGACGTCGAACGGACCCAGCCGCAGACGAGGAAGTGCAAGGAGCACCTGATCGAGGAGGGCCTCACTGAGGTGGGCGACGAGCTGTGCTCGAATCGAGCAATACAGATAATGATCTTTTTCCTGGTGATAATCATGGCAACGTGTCTGTTGGCGGTGTCGACGCTCTACTTTGTCGAGCACAACAAGCAGCGATATGCGAAGCATTACGAGCACTATGAAATTGGCCATCATGCGGGACCGCACGATCCTGTGATGGGCATTGAGAGCAACCCGCGCAATCCCATGCACACTGGGTATCATAGCAACAAAAACGTAAAGTTAAACCAGCACATACACATTCCGCCCCCGTCTGGACCGCGGCCGATCCAGCAGCCGCAGCTCGCGCCAAGGTATCCCTATGTGGGCCTACATCCAACGATCGCCGCAACTGTGATACCACCATCGTATCCGTCCGCTGGAACTGGAGCTCGAGCTAGAGCTGGTCCTGGTCCCGATGTGAGTGCCCTGCGCGCCATCAATCCCGAGGCTGAGCCGTATGAGGCCAACAGAGTGGCAACCAGTGTCGACAAGACGCACGACGATCATCCCAGCAGCATTGAGCGTCCCGTGGTGCCAGGTCTCAGCCTAGCGGCAACAAGCCATTTAAACAACAAGACCGCGAGCAGCAAGAACAAGTCCAAGTGGCCGCTGCCCGACGCAAGTGTGTCGGTGTCATCCACCATAACCCAGGGATACAACTACAATGACGACGCCATCGAGGAGAACATCAACGGCGGCGAGACGTCCTCGGAGAAGGTTGCCGACTCCATACCCTTGCCGCAGGACTTTGAAAATAATTCCATCGACGGGGCGGATGTGTCGGCAAAGCTGGACGCCCGTGCCAGCAATGGCCATGCCAGTGACACAGCCAGTGATCACGGCACAGTGGGCGGCAGCACGTCGAGAAGCAGCGGACACGAGGTGCCCGAGAACAGTGTGGCATCGGTGGGTATCGGCGTGGACACGGCCAATCTTGacagcggcggcggcgatgCGGTGCTAAAGAACATCGAGGGCAACAAGATAAATGACACAATCAGCCAGCATCTGAATTTCACCGTCGAAACACCACCGATCACGAACAAGAGCCGTGGCCTGGACACCGAAGACACAGACCTGCAGTACCTGGGCAACAACAACGACTCCGACGATCAGAATCTCGGCGACATCGGCAACACTCCGATGACAACTAAGTCCTTCACCATAGGCCCCGTCGGAATACCGGAACACTGTGTTAAGATCAAGCGCGAAGAGGTGTCTAATTGTCAGTCGGCTTGCTTTGAGGACACGAACAACCTGCCGTCGCAGACATCGGACAGCGAAATCCACCGGCGGCACATACTCGCCGCCATTACCAACGCATCGAGCAGCTCGATGGCAAATGGAAACAGCCCCAAGGCGCAGTCCCTCATCGATGGCCCAATCGATGTGACCGCCTCGGTGGAACGCGATCAGGTGGAGGACATCGACGACGATCAGGACAACGCATCGTCGCAGTCGCAGGTTTCCCAACAGCAGTTGGACAACAACCGCGAAGAGCTAGCGCTGGCACTGAAGGACAAGAAGCCACCGCACAAGGACGCTAAGCGGAAAGTCGACACAATCGAAGTGAATGAACACAGGACACTGTCCGACTGCACATCGATAACAGCGTGGATGCAAGCGGACACCTTCAACGTGTCGCTGGGATCTGAAGAGGTCTGTCTGAACGGCGGAAGCAGCCTGAACATTACCTACACCATACCCCTGTCCAAGTACTTGAAGGACACCAATTTGGAATTGCATTTTGTGGCGCCAGTTAGTCTACACTGGACAGTGTGTAGTAACAAGGAGACCACCAAGCCCGATGGGAGCGGCGCAATTATTCCACTAAACAACGGAAAGGTTTTCCAGAAAAACCAAAATGTGgcagttttttatttaatcattCCCGGACATGGACATTTTGAGCGTGTGATTAAGCTGCGTGGCGCCATGGATTCAACAAAGAACCTCTGCCGCCAGATAATTGACGAGACAATGGTTATCACGGAGTACAACATTAGAATTCTAAGAGATTGTGAttag
Protein Sequence
MEYTRSLNGRSDFIGGIDNEALDFGLDQFIHVSASTGGTNASPAVSTVDVGTSSTHSAQTQTSLPESPPDSGSEPPYSPGDLQGLTLTSRATSCRCNAATDGTIIGARSPLCSHQQMKTASDIHPLTHIPHQMQPGIHHQHHHLYTDHAEQHSLLLAATPHMHPQGSGIYGSPDNRHDRSVVVHEHPDTLLDIDGHHPKSHVHSNIHVATINEIMDIDAQRSSYSRQPMIMNPQHQHQLTSSIIPSDVYMGTPAPIIETPAVHAPTRKRKLSQVECCTSMLTIKPEPGASMSPMSLQKTNPTSPVTINLQGTDGGSPSLSSLSPTATSLSLSNDNNSLDGVGAGTPNGAGFVGSNGTDSSSESSPMQCIRFSPFQQHNWHTLCDQSLQELTIAHYRVDADKGFNFSVSDDAFVCQKKNHFQITCHARLHGDAKFVRTPSGLEKIKSFHLHFYGVKLEAPNQTIRVEQSQSDRSKKPFYPVPIDLQSHLVSKVTVGRLHFSETTNNNMRKKGRPNPEQRYFQLVVGLHVHTHSGHFPVVSQGSERIIVRASNPGQFESDVELCWQRGITPESIFHAGRVGINTDRPDESLVIHGNLKVSGHIIQPSDSRAKQEISELDTAVQLKNLQKIRIVRYRYEPEFALHSGLKSRMDNEEIVDTGVIAQEVREVLPDAVQEAGSIVLPSGQVIENFLLVNKDRILMENIGAVKELCKVTGSLETRIEQLEKMNKRLLRMQDVERTQPQTRKCKEHLIEEGLTEVGDELCSNRAIQIMIFFLVIIMATCLLAVSTLYFVEHNKQRYAKHYEHYEIGHHAGPHDPVMGIESNPRNPMHTGYHSNKNVKLNQHIHIPPPSGPRPIQQPQLAPRYPYVGLHPTIAATVIPPSYPSAGTGARARAGPGPDVSALRAINPEAEPYEANRVATSVDKTHDDHPSSIERPVVPGLSLAATSHLNNKTASSKNKSKWPLPDASVSVSSTITQGYNYNDDAIEENINGGETSSEKVADSIPLPQDFENNSIDGADVSAKLDARASNGHASDTASDHGTVGGSTSRSSGHEVPENSVASVGIGVDTANLDSGGGDAVLKNIEGNKINDTISQHLNFTVETPPITNKSRGLDTEDTDLQYLGNNNDSDDQNLGDIGNTPMTTKSFTIGPVGIPEHCVKIKREEVSNCQSACFEDTNNLPSQTSDSEIHRRHILAAITNASSSSMANGNSPKAQSLIDGPIDVTASVERDQVEDIDDDQDNASSQSQVSQQQLDNNREELALALKDKKPPHKDAKRKVDTIEVNEHRTLSDCTSITAWMQADTFNVSLGSEEVCLNGGSSLNITYTIPLSKYLKDTNLELHFVAPVSLHWTVCSNKETTKPDGSGAIIPLNNGKVFQKNQNVAVFYLIIPGHGHFERVIKLRGAMDSTKNLCRQIIDETMVITEYNIRILRDCD*

Similar Transcription Factors

Sequence clustering based on sequence similarity using MMseqs2

100% Identity
-
90% Identity
-
80% Identity
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